Coated glass surfaces and method for coating a glass substrate

ABSTRACT

A substrate having a coating is disclosed. The coating is formed of a plurality of layers. At least one of the layers includes a super alloy and at least two additional layers including silver. A coating for a substrate is also disclosed. A method of applying a coating to a substrate is further disclosed.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims benefit of priority to U.S. Ser. No. 61/111,237filed Nov. 4, 2008, the contents of which are herein incorporated byreference.

FIELD OF THE INVENTION

The present invention relates to coatings for substrates or substratesurfaces.

BACKGROUND

Advances in window technology have reduced energy consumption byaffecting and improving heating, cooling and lighting. Optimal windowscan accept solar gain and provide net heating. Optimization may comefrom coatings for windows or glass. Various types of coatings have beendeveloped. Examples include solar control coatings that reflect acrossthe whole spectral range to reduce glare or overheating from the sun,and low-emissivity coatings which reduce radiative heat losses oftenaccounting for significant heat transfer through a window.

Low-emissivity coatings are well known. The coatings generally have ahigh reflectance in the thermal infrared (IR) and a high transmittancein the visible spectrum. Thus, they are low-emissive of thermalinfrared. Some such coatings may admit solar near IR (NIR) to help heata building, such as in a cold climate. Some such coatings may reflectthe NIR back, such as in a warm climate. The low-emissivity opticalproperties are generally obtained by application of a material withcertain intrinsic properties or alternatively, multiple materials may becombined to achieve the particular desired performance. One example of amaterial with relevant intrinsic properties, namely high transmittanceand low-emissivity, may be doped oxides of tin or indium, whereinadjusting the dopant level can tune the wavelength cutoff betweentransmittance and reflectance.

Another class of materials suitable for use in providing low-emissivityincludes very thin films of metals. Thin films forminginfrared-reflection film are generally a conductive metal such assilver, gold or copper. Films of silver are highly reflective. Thereflectance of very thin films can be suppressed by thin-filminterference effects. For example, adding dielectric layers to the frontand back of the metal layer reduces the reflectance of the thin film fora limited range of wavelengths. Coatings including these materials canbe made highly transparent to visible radiation or light, but remainreflective in the NIR. These coatings often include one or two layers ofinfrared-reflection film and two or more layers of transparentdielectric film. The infrared-reflection film reduces the transmissionof heat through the coating. The dielectric film is generally used toanti-reflect the infrared-reflection film and to control otherproperties and characteristics of the coating, such as color anddurability. Such films typically have Light to Solar Gain Ratio (LSG)(visible Light Transmittance divided by the Solar Heat Gain Coefficient)ratios of >1.5. The Solar Heat Gain Coefficient is a measure whichexpresses the proportion of incident solar thermal radiation that istransmitted by a window. Visible Transmittance describes the amount ofvisible light that can pass. Each of these can be independently alteredby different coatings.

Common low-emissivity coatings have one or two silver layers eachsandwiched between two coats of transparent dielectric film. In order toobtain improved performance, some current systems and devices employtriple silver coatings or use a barrier as an absorbing layer. Byincreasing the number of silver films, the infrared reflection can beincreased. Unfortunately, increasing the number of silver films alsoreduces visible light transmission and can negatively affect the colorof the coating or decrease durability of the coating. For example,triple silver coatings have a dominant green appearance that isundesirable. Moreover, it is difficult to control the color of thecoating, which can lead to color inconsistency.

Accordingly, a coating for a glass substrate is provided which providesimproved performance, color control or improvement, and ease ofmanufacture over currently available coatings and devices.

SUMMARY OF THE INVENTION

A substrate comprising a coating is provided. The coating is formed of aplurality of layers. At least one of the layers includes an alloy orsuper alloy. At least two additional layers are provided includingsilver.

A coating for a substrate is also provided. The coating includes analloy or super alloy layer, a first silver layer, and a second silverlayer.

A method of coating a substrate is further provided. The method includesthe steps of forming a coating by applying a first layer to a substrateby sputtering, the first layer including an alloy or super alloy. Asecond layer is applied to the substrate by sputtering, the second layerincluding a silver material. A third layer is also applied to thesubstrate by sputtering, the third layer including a metal, wherein thefirst, second and third layers form at least a portion of a coating forthe glass substrate.

The foregoing coating and method provide advantages over currentlyavailable devices. By use of an alloy or super alloy such as, forexample, a nickel-chromium-molybdenum alloy or super alloy, transmissionthrough a substrate can be attenuated. More specifically, a highreflectance in the thermal infrared (IR) and a high transmittance in thevisible spectrum may be obtained. The coating on the substrate surfaceformed of low-emissive material may reflect a significant amount ofradiant heat, thus lowering the total heat flow through the substrate.The low-emissive coating may also be arranged to allow for high solargain, for moderate solar gain, or for low solar gain, by varying theamount of visible light and/or radiation permitted to pass through thesubstrate. The coating offers significant improvements in solar heatgain/visible light ratios. For example, the coating, when built to aninner surface, such as the #2 surface of an insulating glass substrate,may include a visible light transmission in the range of about 20% toabout 50%. The coating also provides ease of manufacturing and ease ofcontrol of the color of the coating as compared to other coatings withcomparable performance.

The coating layer system may also minimize the potential for colorinconsistency when viewed perpendicular to the glass surface or at acuteangles. For example, a coated article may be provided. The coatedarticle may include a substrate having a pair of major surfaces and acoating applied to at least one of the major surfaces. The coating mayinclude a plurality of layers. The color coordinate values of the coatedarticle from a direction that is substantially normal to the coatedmajor surface may be substantially equal to the color coordinate valuesfrom directions that are acute to the coated major surface. In addition,or alternatively, the variation in color coordinate values of thearticle from a direction that is substantially normal to the coatedmajor surface to the color coordinate values from directions that areacute to the coated major surface may be reduced relative to knowncoated articles. To this end, the coating appeals to a wide range ofdesigns and building applications. Other advantages and features maybecome apparent from the following description, drawings, and claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating the coating on a substrate according toone example of an embodiment of the present invention.

FIG. 2 is a diagram illustrating the coating on a substrate of FIG. 1,including examples of suitable layer material.

FIG. 3 is a schematic diagram illustrating an example of a coater usefulfor one example of a method for producing a coating on a substrate asshown in FIG. 1.

FIG. 4 is a partial cross-sectional view of the coating of FIG. 1applied to an IG unit according to one example of an embodiment of thepresent invention.

FIG. 5 is a graph, showing glass side reflection values at variouswavelengths ranging from 380 nm to 780 nm of samples of the describedcoating with increasing amounts of a nickel-chromium-molybdenum alloy.Example 1 has the thickest layer, while Example 5 has the thinnest.

FIG. 6 is a graph, showing film side reflection curves for Examples 1through 5.

FIG. 7 is a graph, showing transmission curves for Example 1 through 5.

DETAILED DESCRIPTION OF THE INVENTION

The invention is generally directed to a substrate having a coatingthereon. More particularly, the invention is directed to a substrate 20having a coating, which may be a low-emissivity coating. Also providedare methods and equipment for depositing the coating.

The substrate 20 may be any transparent, substantially transparent, orlight transmissive substrate such as glass, quartz, any plastic ororganic polymeric substrate, or any other suitable material orcombination of materials. Further, the substrate may be a laminate oftwo or more different materials and may be a variety of thicknesses. Thesubstrate 20 may also be arranged to include low-emissive properties,apart from a film or coating, such as, for example, as can beaccomplished by controlling the iron content in a glass substrate. Inone embodiment, the substrate 20 is float glass. Alternatively, thesubstrate 20 may be a type of glass having low-emissive properties, suchas, but not limited to a borosilicate or PYREX™.

The coating 10 may be a thin film coating. To this end, a low-emissivitycoating 10 is applied to a surface of a substrate 20. As describedherein, the coating 10 may be one or more low-emissivity coatings andmay be a microscopically thin, virtually invisible, metal layer or metaloxide layer or plurality or combination of said layers deposited on asubstrate 20 surface. The low-emissivity coating 10 may be transparentor substantially transparent to visible light, and may be opaque orsubstantially opaque to infrared radiation. To this end, the coating 10on the substrate 20 surface may be formed of low-emissive material andalternatively may be arranged to allow for varying amounts of, forexample, solar gain by varying the amount of visible light and/orradiation permitted to pass through the substrate 20. The low-emissivitycoating 10 has the general properties of reflecting radiant infraredenergy, thus tending to keep radiant heat on the same side of the glassfrom which it originated.

The coating 10 may be arranged in a layer system as shown in FIG. 1. Inan example of an embodiment, the layer system is composed of a pluralityof layers on or otherwise attached to the substrate 20. To this end, thefilm region may be a single layer or a plurality of layers. Thus, one ormore of the films or a plurality of film regions may form the coating 10of an example of an embodiment. The film regions are provided in theform of layers. The thickness of the layer or layers may be uniform, ormay vary. Likewise, the thickness of an individual layer may vary acrossits width or length. In one example, the film region or a portionthereof may have or include a gradual change or graded thickness acrossat least a portion thereof. For example, the layer may, in someinstances, increase in thickness or decrease in thickness withincreasing distance from the substrate. The one or more layers may beprovided in a contiguous relationship, that is directly on top of oradjacent to another layer or the substrate.

One or more layers of the coating 10 may include or be based on metallicoxides and may be applied to one or more surfaces of the substrate 20.In this regard, as can be seen in FIG. 1, a bottom oxide layer 22, amiddle oxide layer 30 and a top oxide layer 36 are provided. These oxidelayers each form generally a transparent dielectric film region which isapplied over a surface or over a reflective region or layer. Usefuldielectric film materials include oxides of zinc, tin, indium, bismuth,titanium, hafnium, zirconium, and alloys thereof, as well as siliconnitride and/or silicon oxynitride. While oxides are specificallyreferenced herein, alternative dielectric materials may be suitable forpurposes of the present invention. In the examples provided herein, andas shown in FIG. 2, the dielectric layers or oxide layers may be formedof zinc oxide (ZnO), tin oxide (SnO₂) or mixtures thereof. To this end,an oxide layer or transparent dielectric film region may be formed of orinclude a zinc tin oxide mixture. A dielectric film region may be asingle layer of a single dielectric material or may include two or morelayers of the same or different dielectric materials. It should beunderstood that throughout the specification reference is made to metaloxides. This should not be considered limited to fully oxidized metaloxides but also those species that can form an agglomeration and havepartial oxidation states. They can be designated as a M(metal)ox(oxide),e.g., Tiox, Snox, etc.

The bottom oxide layer 22 may have a thickness ranging from about 360 Ato about 400 A (A=angstroms). The middle oxide layer 30 may have athickness ranging from about 550 A to about 700 A. The top oxide layer36 may have a thickness ranging from about 110 A to about 140 A. In thisregard, the middle oxide layer 30 has a thickness which is greater thanthe thickness of the top and bottom oxide layers 36, 22. From an opticsstandpoint the top oxide and Tiox layer can be treated as single layer.

As can be seen in FIGS. 1-2, the bottom oxide layer 22, substantiallyidentical to that described above, is deposited or placed or otherwiseattached on a surface of the substrate 20. The bottom oxide layer 22 maybe formed of any suitable material, and in the example shown in FIG. 2includes zinc oxide and/or tin dioxide (ZnO/SnO₂) within the layer.

The bottom oxide layer 22 may be in contiguous relationship, or directphysical contact with a face of a film region 24, or may be separatedtherefrom. In an example of an embodiment, the second layer may includeor be composed of a substance, such as a ceramic, polymer, or metal,which could be an alloy or a super alloy. More specifically, the secondlayer may be a nickel-based alloy or super alloy, or an austeniticnickel-based alloy or super alloy. More preferably, the alloy or superalloy may be a nickel/chromium/molybdenum (hereinafter an “NCM”) alloy,for example INCONEL™, such as INCONEL™ 625. Inconel™ 625 is an NCM alloycomposed of Ni (about 58% minimum), Cr (about 20 to about 23%), Mo(about 8 to about 10%), Nb+Ta (about 3.15 to about 4.15%) and Fe (about5% maximum) by weight. Typical Properties of Inconel™ 625 include adensity of 8.44 g/cm³, a melting point of about 1350° C., a co-efficientof expansion of 12.8 μm/m° C. (20-100° C.), a modulus of rigidity of 79kN/mm², and a modulus of elasticity of 205.8 kN/mm². Inconel™ 625 iscovered by the following standards: BS 3076 NA 21, ASTM B446 and AMS5666. Inconel™ 625 is available from, and is the tradename of SpecialMetals Corporation of Huntington, W. Va. For purposes of the examplesprovided herein, INCONEL™ may be obtained for use in any suitable form.INCONEL is available in several different alloys, although alternativeforms will not depart from the overall scope of the present invention.Inconel™ 625 is equivalent to: W.NR 2.4856 (Multi-Alloys cc, SouthAfrica), UNS N06625 (Sandmeyer Steel Co., Philadelphia, Pa.) and is alsoknown as AWS 012 as well as under common trade names of Chronin® 625,Altemp® 625, Haynes® 625, Nickelvac® 625 and Nicrofer® 6020.

Accordingly, adjacent the bottom oxide layer 22, as can be seen in FIGS.1-2, is a second, or NCM alloy layer 24. The NCM layer 24 may bedeposited on the bottom oxide layer 22 or otherwise attached thereto.The NCM layer 24 may have a thickness ranging from about 30 A to about150 A. The NCM layer may form an infrared reflection region or may forma portion thereof. The NCM alloy may advantageously form an oxide layerwhen heated and retain strength over a wide temperature range. While NCMalloys are specifically described, other alloys or super alloys suitablefor use in high temperature applications which may have one or more ofoxidation and corrosion resistant properties or are otherwise suited forextreme environments or have excellent mechanical strength and creepresistance at high temperature, and/or good surface stability may beacceptable for use with the present invention. NCM alloys may besputtered in an inert atmosphere to provide a layer composition whichmay be applied to the substrate 20.

In addition to an alloy or super alloy layer, a metal layer or film 26may also be applied. To this end, a metal such as a silver, a copper, ora gold, and alloys thereof may be applied to the substrate 20, and moreparticularly to the substrate 20 with one or more layers thereon.Accordingly, as shown in FIG. 1, contiguous with the NCM film region 24or layer is a metal layer 26 forming an infrared reflective film region.This film region 26 may include a suitable reflection material, and inparticular an infrared-reflection material, such as but not limited tosilver, gold and/or copper, as well as alloys thereof. The metal layerin one example is a silver layer 26. In an example of an embodiment, thereflection film is formed of silver or silver combined with anothermaterial, such as another metal including, but not limited to copper,gold, platinum, palladium. The material is formed into a compositionwhich may be applied as a layer or film 26 to the substrate 20 or layersthereon. The silver layer 26 may likewise be deposited on the NCM alloylayer 24 or otherwise attached thereto. Accordingly, as can be seen inFIGS. 1-2, the NCM alloy layer 24 is positioned between the bottom oxidelayer 22 and a first silver layer 26. The metal layer or silver layer 26may have a thickness ranging from about 80 A to about 150 A.

A protective or barrier layer 28 may also be optionally provided (seeFIG. 1). The barrier layer 28 may be deposited on the silver layer 26 orotherwise attached thereto. In one embodiment, the barrier 28 may beformed of a material which is readily oxidized. To this end, as shown inFIG. 2, the barrier 28 may be a layer of titanium metal or may be atitanium oxide (or a portion thereof may be a titanium oxide). In anexample of an embodiment, as shown in FIGS. 1-2, the barrier layer 28may be contiguous with a reflective film region 26. To this end, thesilver layer of FIGS. 1-2 may be positioned between the NCM alloy layer24 and a first barrier layer 28, such as a titanium layer.

The middle oxide layer 30, formed as described in detail herein, may beprovided contiguous to the barrier layer. To this end, the barrier layer28, as shown in FIG. 1, may be further positioned between the firstsilver layer 26 and the middle oxide layer 30. The middle oxide layer 30is deposited or otherwise attached to the barrier layer.

A second or additional metal layer or infrared reflective film region32, substantially similar to the reflective film region 26 or firstsilver layer discussed above, may also be provided and applied to thesubstrate 20 or layers thereon. The second metal or second silver layer32, as shown in FIGS. 1-2, is positioned adjacent the middle oxide layer30 and may be deposited or otherwise attached to the middle oxide layer30. More specifically, the second or additional metal layer 32 may beprovided contiguous with the middle oxide layer 30. The second silverlayer 32 may have a thickness ranging from about 80 A to about 150 A.The second or additional metal layer 32 is substantially as describedwith respect to metal layer 26 discussed hereinabove and will,therefore, not be discussed in further detail herein.

An additional protective or barrier layer 34 may be provided contiguouswith, and may be deposited or otherwise attached to the second silverlayer 32 (see FIG. 1). The second barrier 34 layer may have a thicknesssuitable to help protect the coating. The second barrier 34 layer issubstantially as described with respect to barrier layer 28, and willtherefore not be discussed in further detail herein.

The second barrier 34 layer may be positioned between the second silverlayer and the top oxide layer 36 (see FIG. 1). The top oxide layer 36 isdescribed in detail hereinabove. The top oxide layer 36 may becontiguous with and may further be deposited or otherwise attached onthe barrier layer 34.

The top oxide layer 36 may also optionally carry or include an overcoat38 attached to a surface and may be contiguous therewith (see FIG. 1).In this regard the top oxide layer 36 may be positioned between thesecond barrier 34 layer and the overcoat 38. The overcoat 38 may becomposed of or include a metal such as titanium or may be formed of atitanium oxide (TiOx) as shown in FIG. 2. The overcoat 38 of the coatinglayers may have a thickness ranging from about 130 A to about 150 A. Theovercoat 38 may have a surface which is exposed or otherwise facing theenvironment in which the substrate 20 with coating 10 thereon is placed.

According to the foregoing arrangement, a substrate 20 has deposited onits surface a sandwich-type arrangement of film layers forming a coating10, including an NCM alloy layer 24 below a first silver layer 26, whichis below a second silver layer 32. The coating 10 layers further mayinclude a bottom oxide layer 22 between the NCM alloy layer 24 and thesubstrate 20, a middle oxide layer 30 between the first and secondsilver layers 26, 32, and a top oxide layer 36 above the second silverlayer. Barrier layers 28, 34 may also be provided between the silverlayers and oxide layers. While the foregoing layers are described asbeing contiguous, it is contemplated that materials or layers may beplaced between the respective layers suitable for the intended purposesof the coating without departing from the overall scope of the presentinvention.

The foregoing described coating 10 may be used with any transparent,substantially transparent, or light transmissive substrate 20. Thesubstrate 20 may be used in a variety of arrangements and settings wherecontrol of reflectance and transmittance is required or desired. In oneexample of an embodiment, the substrate 20 may be used as, or form awindow or skylight. To this end, the coating 10 may be combined with awindow pane. The window pane may also have unique properties, such asinsulating properties. Accordingly, as shown in FIG. 4, in one exampleof an embodiment, the low-emissivity coating 10 is applied to a surfaceof an insulating glass or IG window unit 60. As shown, the IG unit 60may be a multi-pane window having a first pane, or sheet of glass 62,and a second pane, or sheet of glass 64, sealed at their peripheraledges by a conventional sealant 66 to form a chamber 68 therebetween. Bysealing the peripheral edges of the glass sheets 62, 64 and introducinga low-conductance gas, such as argon, into the chamber 68, a typical,high insulating value IG unit is formed. In one example of anembodiment, the coating 10 may be applied on an inner surface 72 ofglass sheet 62 within the chamber 20, as illustrated, or alternativelyon inner surface 74 of the glass sheet 64 within chamber 20 (not shown).In this respect, it is to be appreciated that FIG. 4 illustrates onlyone embodiment of an IG unit in which the coating of the presentdisclosure may be employed. For example, the coatings of the presentdisclosure may applied to an IG unit having more than two panes ofglass.

In some embodiments, the low-emissivity coating 10 may be a thin coatingon the substrate 20 or window pane within its airspace that reflectsthermal radiation or inhibits its emission, reducing heat transferthrough the glass. The low-emissivity coating 10 may thus be positionedon an interior surface or face of the glass or may be located on theoutside pane of the glass and may further be provided with additionalfeatures, such as but not limited to a film or a body tint which can beused to further reflect solar radiation, or may also include polarizingmaterials. The substrate 20 may be further retained by a window frame.The window frame may likewise have unique features, such as an insulatedwindow frame that minimizes conductive heat transfer.

A variety of methods may be used to apply the coating 10, or the filmsor layers forming the coating described herein. In an example of amethod of forming a coating 10 on a substrate having a surface isprovided. This surface may be optionally prepared by suitable washing orchemical preparation. A coating 10 may be deposited on the surface ofthe substrate. The coating 10 may be deposited in one or more of aseries of discrete layers, or as a thickness of graded film, orcombinations thereof. The coating 10 can be deposited using any suitablethin film deposition technique.

In one example of an embodiment, sputtering may be used to deposit orapply the coating on the substrate. As is known, sputtering is atechnique used to deposit thin films of a material onto a surface orsubstrate. By first creating a gaseous plasma and then accelerating theions from this plasma into some source material (i.e., a target), thesource material is eroded by the arriving ions via energy transfer andis ejected in the form of neutral particles, either individual atoms orclusters of atoms or molecules. As these neutral particles are ejectedthey travel in a straight line unless they come into contact withsomething, whether it is another particle or a nearby surface. Asubstrate placed in the path of these ejected particles will be coatedby a thin film of the source material or target. As is known, a gaseousplasma is a dynamic condition where neutral gas atoms, ions, electronsand photons exist in near balanced state simultaneously. One can createthis dynamic condition by metering a gas, such as argon or oxygen into apre-pumped vacuum chamber and allowing the chamber pressure to reach aspecific level and then introducing a live electrode into this lowpressure gas environment using a vacuum feed through. An energy source,such as RF, DC, MW may be used to feed and thus maintain the plasmastate as the plasma loses energy into its surroundings. The type ofsputtering used may be diode sputtering, magnetron sputtering, confocalsputtering, direct sputtering or other suitable techniques.

In the example provided herein of a method of depositing the coating 10,DC magnetron sputtering is used. Magnetron sputtering involvestransporting a substrate 20 through a series of low pressure zones inwhich the various film regions that make up the coating 10 aresequentially applied. Thus, the metallic films are sputtered frommetallic sources or targets, which may occur in an inert atmosphere. Todeposit transparent dielectric film or oxide layers, the target may beformed of the dielectric itself. Alternatively, the dielectric film mayalso be applied by sputtering a metal target in a reactive atmosphere.In this regard, for example to deposit zinc oxide, a zinc target can besputtered in an oxidizing atmosphere. The thickness of the depositedfilm may be controlled by varying the speed of the substrate and/or byvarying the power placed upon the targets. In an alternative embodimentof a method for depositing thin film on a substrate, plasma chemicalvapor deposition may be used. Such plasma chemical vapor depositioninvolves the decomposition of gaseous sources via a plasma andsubsequent film formation onto solid surfaces, such as glass substrates.The film thickness can be adjusted by varying the speed of the substrateas it passes through a plasma zone and/or by varying the power and/orgas flow rate within each zone.

In one example of a method for depositing a coating 10, a coater,represented generally by 40 in FIG. 3, is used to deposit a coating inthe arrangement described herein which may include, in sequence from thesubstrate 20 surface outward toward an exposed environment, a firsttransparent dielectric film region or bottom oxide layer 22, a superalloy region 24, a first infrared-reflection film region or silver metalregion 26, a first barrier 28 region, a second transparent dielectricfilm region or middle oxide layer 30, a second infrared-reflection filmregion or silver metal region 32, a second barrier 34 region, a thirdtransparent dielectric film region or top oxide layer 36, and anoutermost layer or overcoat 38. A suitable coater is a architecturalglass coater available from Applied Films. Generally, a coater with aminimum of 22 cathode positions and the ability to achieve vacuum ofapproximately 10⁻⁶ ton is desirable.

Referring to FIG. 3, to accomplish the foregoing coating arrangement,the substrate 20 is positioned at the beginning of the coater 40 andconveyed, by conveyor assembly (not shown), into the first coat zone 42,and then subsequently through a plurality of additional proximallypositioned coat zones. It is understood that conveying may beaccomplished by any suitable means, mechanical, computerized, or by handoperation. In one example, the conveyance of the substrate may be bytransport rollers on a conveyor assembly. Each coat zone may be providedwith one or more sputtering chambers or bays adapted to collectivelydeposit a film region on the substrate. In each of the bays are mountedone or more targets including a sputterable target material. In theexamples provided herein, the target may be a compound of zinc or tin,or a metal or metal compound.

The first coat zone 42 is provided with three sputtering chambers (or“bays”) which are adapted collectively to deposit a first transparentdielectric film region or bottom oxide layer 22 comprising zinc tinoxide. All three of these bays are provided with sputtering targetscomprising a compound of zinc or tin. The number and type of sputteringtargets, i.e., planar or cylindrical, and the like, can be varied formanufacturing or other preferences. The targets are sputtered in anoxidizing atmosphere to deposit the first transparent dielectric filmregion or bottom oxide layer 22 in the form of an oxide film comprisingzinc and tin having a thickness of between about 365 A and about 400 A.

The substrate is then conveyed into a second coat zone 44 wherein an NCMalloy layer 24 and a silver layer 26 forming a first infrared-reflectionfilm region are applied directly over or contiguous with the firsttransparent dielectric film region or bottom oxide layer 22. The secondcoat zone 44 is provided with an inert atmosphere. In one example, theinert atmosphere includes argon, although alternative inert gases may beused without departing from the overall scope of the present invention.The active sputtering bays of this coat zone each have a target. Thenumber and type of target, i.e., planar or cylindrical or the like, canbe changed for purposes suitable to the manufacture or otherwise asdesired. The first target in a bay may be an NCM alloy target. Thetarget in the subsequent or adjacent bay may be a metallic silvertarget. The target in a further subsequent bay may be a metallictitanium target. As with the first coat zone 42, the substrate isconveyed beneath the NCM alloy target, thereby depositing the NCM alloyin the form of a film having a thickness of between about 30 A and about40 A. The substrate is then conveyed under the silver target, depositingthe silver in the form of a film having a thickness of between about 90A and about 120 A. As a result, the first infrared-reflection filmregion is deposited in the form of an NCM alloy film and a silver filmcontiguous therewith, having a thickness of between about 120 A andabout 160 A. The substrate is then conveyed beneath the titanium targetin the next bay, thereby depositing a first barrier 28 region in theform of a film comprising titanium and having a thickness suitable toprotect the silver layer 26 from oxidation.

The substrate is subsequently conveyed through a third coat zone 46 anda fourth coat zone 48, in which zones the second transparent dielectricfilm region or middle oxide layer 30 is applied in the form of an oxidefilm comprising zinc and tin. The third and fourth coat zones 46, 48each have three active sputtering bays. The third and fourth coat zones46, 48 are substantially similar to that described with respect to thefirst coat zone 42, and sputtering occurs substantially as describedwith respect to the first coat zone 42. In this regard, the oxidizingatmospheres in the third and fourth coat zones 46, 48 may each consistof or include oxygen. Alternatively, one or more of these atmospherescan comprise argon and oxygen. The targets of coat zone three mayinclude first and second zinc targets in adjacent bays and a tin targetwhich forms the third target in a third bay in the coat zone. Thetargets may be formed of any suitable type, such as a planar orcylindrical target or the like, or may be provided in any numbersuitable for the purposes provided. The fourth coat zone 48 may includea first bay with a tin target and two subsequent bays with zinc targets,forming second and third targets. The substrate is conveyed beneath allof the noted targets in coat zones three and four 46, 48, such that thesecond transparent dielectric film region or middle oxide layer 30 isapplied in the form of an oxide film comprising zinc and tin and havinga thickness between about 600 A and about 700 A.

Following the fourth coat zone 48, the substrate is conveyed through afifth coat zone 50 which has two active sputtering bays. In the fifthcoat zone 50 the second infrared-reflection film region or silver layer32 is applied directly over or contiguous with the second transparentdielectric film region or middle oxide layer 30. Sputtering occurssubstantially as described with respect to the first infrared-reflectionfilm region. In this regard, the fifth coat zone 50 has an inertatmosphere, which may be formed by argon gas. The sputtering bays inthis coat zone each have a target. The target may be a planar target orcylindrical target or the like. Each bay may also include a plurality oftargets. The target in the first bay is a metallic silver target, andthe target in the adjacent chamber is a metallic titanium target. Themetallic titanium target forms barrier layer 34. The substrate isconveyed beneath the target in the first bay to deposit the secondinfrared-reflection film region as a metallic silver film having athickness of between about 95 A and about 110 A. The substrate is thenconveyed at the same rate beneath the metallic titanium target in theadjacent bay to deposit a second barrier 34 film region comprisingtitanium.

The substrate is then conveyed through a sixth coat zone 52 where thethird transparent dielectric film region or top oxide layer 36 isapplied. The coat zone in the example provided has two sputtering bays,and each such bay is provided may be provided with one or more targets.The targets may be any suitable shape or type as described herein andmay comprise a sputterable material that is a compound of zinc or tin.The coat zone 52 is provided with an oxidizing atmosphere includingoxygen. Alternatively, this atmosphere may comprise argon and oxygen.The substrate is conveyed beneath these targets in coat zone 52 suchthat the third transparent dielectric film region or top oxide layer 36is applied as an oxide film comprising zinc and tin and having athickness of between about 110 A and about 135 A.

The substrate is conveyed into a seventh coat zone 54 and an eighth coatzone 56, wherein the outermost portion of the third transparentdielectric film region or top oxide layer, namely, the overcoat 38, isapplied. The seventh and eighth coat zones 54, 56 each have twosputtering bays, and each contain an oxidizing atmosphere consistingessentially of oxygen. Alternatively, this atmosphere may compriseargon, nitrogen and/or oxygen. The sputtering bays in each of these coatzones are each provided with one or more targets of any type, such asbut not limited to cylindrical or planar targets. Each of these targetscomprises a sputterable target material of titanium or a titanium oxide.The substrate is conveyed beneath all of the targets in seventh andeighth coat zones such that the overcoat layer 38 or portion of thethird transparent dielectric film region or top oxide layer 36 isapplied as a titanium oxide film comprising and having a thickness ofbetween about 125 A and about 145 A.

It is understood that while a specific arrangement and number of coatzones and active sputtering bays may be described, there may be unusedbays and/or coat zones positioned between one or more of theabove-described zones and bays. Likewise, alternative positions, numbersand variations of the various components may be used without departingfrom the overall scope of the present invention. Furthermore, whilemagnetron sputtering is specifically described, in an alternativeexample of a method of applying a coating 10, the coating 10 may bepreformed and applied to a substrate 20, such as by an adhesive.Alternatively, the coating 10 or properties thereof may be integrallyformed with the substrate 20.

EXAMPLES

The following examples are presented as illustrations of the coating 10and method of applying a coating 10 on a substrate and are not intendedto limit the overall scope of the present invention.

As can be seen from the following examples, the coating 10 and method ofapplication of the coating 10 described herein provides reduced lighttransmission from existing low-emissive coating 10 and providesappropriate exterior color.

The coating 10 having the properties described herein were testedaccording to National Fenestration Rating Council (NFRC) methodsfollowing NFRC 200-2004[E1A4] Procedure for Determining FenestrationProduct solar heat Gain Coefficient and Visible Transmittance at NormalIncidence, which is hereby incorporated by reference in its entirety.The coating 10 was also tested in accordance with NFRC 301-2004 StandardTest Method for Emittance of Specular Surfaces Using SpectrometricMeasurements, which is hereby incorporated by reference in its entirety.As can be seen from the following Tables and FIGS. 5, 6 and 7, resultsare listed using color space values, or Hunter Lab, including %transmission (T) or transmission in the a-axis of transmitted color (Tah); transmission in the b-axis of transmitted color (T bh); %reflectance glass side (RG); reflectance glass side in the a-axis (RGah); reflectance glass side in the b-axis (RG bh); % reflectance filmside (RF); reflectance film side in the a-axis (RF ah); reflectance filmside in the b-axis (RF bh). The color values (Tah, Tbh, RGah, RGbh, RFahand RFbh) are relative numbers on the Hunter Lab Color Space. ASTMC1649-08 Standard Practice for Instrumental Transmittance Measurement ofColor for Flat Glass, Coated and Uncoated and ASTM C1650-07 StandardPractice for Instrumental Reflectance Measurement of Color for FlatGlass, Coated, and Uncoated. The ah values represent the green (−ah) tored (+ah) and the bh values represent the blue (−bh) to yellow (+bh). T,RG, and RF values are % (either % transmission (T) or % reflection (RGand RF).

Examples 1 Through 5

The Examples 1-5 listed in Tables 1 and 2 below, provide five differentiterations (Examples 1 through 5) of the coating layer system which havediffering amounts of visible light transmission and associatedproperties. The amount of NCM alloy deposited in each example has beenvaried. The coatings were all produced in accordance with the depositingmethods disclosed herein, and with the set up (power levels) as shownbelow. The higher the power the more NCM alloy was deposited. Inconel™625 was used as the NCM alloy. An argon atmosphere was used with for themetal zones, a oxygen atmosphere was used for the metal oxide zones anda mixture of oxygen and nitrogen was used for the overcoat layer. Actuallayer thickness during production trials were not measured, but powerlevels and line speeds are monitored to determine how much material isbeing deposited. This work was performed on a 24 chamber, BOC design,architectural glass coater.

Table 2 further includes, for purposes of comparison, performance dataanalogous to that of Examples 1-5 for a conventional double silvercoating and a conventional triple silver coating. Particularly, thedouble silver coating is a VE-2M coating, and the triple silver coatingis a VNE-63, each of the coatings commercially available from Viracon,Inc., of Owatonna, Minn. The performance characteristics for theconventional double and triple silver coatings were computed accordingto the software program WINDOW 5.2.

TABLE 1 Metal Example 1 Example 2 Example 3 Example 4 Example 5 Ti 78 kW78 kW 78 kW 78 kW 78 kW Ti 78 kW 78 kW 78 kW 78 kW 78 kW Ti 78 kW 78 kW78 kW 78 kW 78 kW Ti 78 kW 78 kW 78 kW 78 kW 78 kW Ti 78 kW 78 kW 78 kW78 kW 78 kW Sn 19 kW 19 kW 19 kW 19 kW 19 kW Zn 19 kW 19 kW 19 kW 19 kW19 kW Ti 4.0 kW  4.0 kW  4.0 kW  4.0 kW  4.0 kW  Ag 8.2 kW  8.2 kW  8.2kW  8.2 kW  8.2 kW  Zn 34 kW 34 kW 34 kW 34 kW 34 kW Zn 34 kW 34 kW 34kW 34 kW 34 kW Sn 34 kW 34 kW 34 kW 34 kW 34 kW Sn 34 kW 34 kW 34 kW 34kW 34 kW Zn 34 kW 34 kW 34 kW 34 kW 34 kW Zn 34 kW 34 kW 34 kW 34 kW 34kW Ti 4.0 kW  4.0 kW  4.0 kW  4.0 kW  4.0 kW  Ag 5.6 kW  5.6 kW  5.6 kW 5.6 kW  5.6 kW  INCONEL 13.6 kW   9.2 kW  7.5 kW  5.8 kW  4.3 kW  625 Zn33 kW 33 kW 33 kW 33 kW 33 kW Sn 33 kW 33 kW 33 kW 33 kW 33 kW Zn 33 kW33 kW 33 kW 33 kW 33 kW

TABLE 2 Color & Emissivity Double Triple (Monolithic¹) Example 1 Example2 Example 3 Example 4 Example 5 Ag Ag T 24.69 37.11 43.61 48.92 55.2279.10 69.92 Tah −6.78 −7.41 −7.48 −7.08 −5.67 −3.62 −4.11 Tbh −1.89−1.54 −0.81 −0.14 0.70 2.74 3.77 RG 21.87 15.40 12.73 11.05 9.09 6.006.12 Rgah −2.93 −3.58 −3.34 −3.20 −0.61 1.76 −0.08 RGbh 0.18 −3.59 −5.76−6.69 −8.34 −1.73 −2.04 RF 14.98 7.90 5.76 4.71 4.11 4.67 3.14 RFah 6.6810.99 11.90 10.85 5.16 −1.93 0.97 RFbh −9.04 −9.99 −10.19 −10.15 −6.841.01 −2.17 Emissivity 0.03 0.04 0.032 Performance (IG Unit²)Transmittance Visible Light (%) 21.8 32.6 38.4 43.1 48.7 70 62 SolarEnergy (%) 8.4 13.0 15.5 17.6 20.44 32 23 Ultraviolet (%) 2.0 3.3 4.04.6 5.3 10 4 Reflectance Visible exterior (%) 23.2 17.1 14.6 13.3 11.811 10 Visible interior (%) 26.2 14.4 12.6 11.8 11.3 12 11 Solar energy(%) 25.3 23.8 24.0 24.4 26.5 31 36 NFRC U-Value Winter 0.292 0.293 0.2920.294 0.291 0.29 0.29 Summer 0.259 0.260 0.258 0.261 0.256 0.26 0.25Shading Coefficient. (SC) 0.160 0.218 0.246 0.270 0.299 0.44 0.32 SolarHeat Gain 0.143 0.189 0.212 0.233 0.259 0.38 0.28 Coefficient (SHGC)¹monolithic glass is ¼″ clear with coating on the #2 surface ²IG unitconsists of ¼″ clear with coating on the #2 surface - ½″ air space - ¼″clear glass

FIGS. 5, 6 and 7 provide glass side reflection values, film sidereflection curves, and transmission curves for Examples 1 through 5.

The foregoing coating and method provides advantages over currentlyavailable coated substrates, particularly substrates coated withconventional double silver and triple silver coatings. As can be seen bythe foregoing examples, particularly with respect to Example 5, by theaddition of an alloy or super alloy material, such as an NCM alloy, to adouble silver coated substrate, performance superior to that of aconventional double silver coated substrate, and comparable to that of aconventional triple silver coated substrate, can be achieved whilemaintaining desired color levels. More specifically, the coatedsubstrates of the present disclosure have an emissivity comparable tothat of conventional triple silver coatings, while maintaining atwo-silver layer design. This is particularly advantageous given that itallows for depositing of the coating using an 8 chamber coating machine,as opposed to the much larger and more costly 8+ chamber coatingmachines required for conventional triple silver coatings. Moreover, thecoated substrates of the present disclosure have a desirable, dominantblue appearance (i.e., a b_(h) color coordinate value of −8.34) asopposed to the undesirable, dominant green appearance of conventionaltriple silver coated substrates. Still further, as can be seen by theforegoing examples, particularly Example 5, an IG unit coated inaccordance with the present disclosure has an improved SHGC valuerelative to both the conventional double and triple silver coated IGunits, while maintaining a desirable visual light transmittance (˜50%).

As indicated, the low-emissivity coating 10 may be transparent orsubstantially transparent to visible light, and may be opaque orsubstantially opaque to infrared radiation. To this end, the coating 10on the substrate 20 surface formed of the low-emissive materialdescribed may reflect a significant amount of radiant heat, thuslowering the total heat flow through the glass. The low-emissivitycoating may also, therefore, be arranged to allow for high solar gain,for moderate solar gain, or for low solar gain, by varying the amount ofvisible light and/or radiation permitted to pass through the substrate20. The coating further includes a visible light transmission in therange of about 20% to about 50%. Furthermore, the coating provides aLight to Solar Gain Ratio (LSG) (visible Light Transmittance divided bythe Solar Heat Gain Coefficient) of approximately 1.9.

The coating also provides ease of manufacturing and ease of control ofthe color of the coating as compared to other coatings with comparableperformance. The coating layer system also minimizes the potential forcolor inconsistency when viewed perpendicular to the glass surface or atacute angles. To this end, the coating appeals to a wide range ofdesigns and building applications.

Although various representative embodiments of this invention have beendescribed above with a certain degree of particularity, those skilled inthe art could make numerous alterations to the disclosed embodimentswithout departing from the spirit or scope of the inventive subjectmatter set forth in the specification and claims. Joinder references(e.g., attached, coupled, connected) are to be construed broadly and mayinclude intermediate members between a connection of elements andrelative movement between elements. As such, joinder references do notnecessarily infer that two elements are directly connected and in fixedrelation to each other. In some instances, in methodologies directly orindirectly set forth herein, various steps and operations are describedin one possible order of operation, but those skilled in the art willrecognize that steps and operations may be rearranged, replaced, oreliminated without necessarily departing from the spirit and scope ofthe present invention. It is intended that all matter contained in theabove description or shown in the accompanying drawings shall beinterpreted as illustrative only and not limiting. Changes in detail orstructure may be made without departing from the spirit of the inventionas defined in the appended claims.

Although the present invention has been described with reference topreferred embodiments, persons skilled in the art will recognize thatchanges may be made in form and detail without departing from the spiritand scope of the invention.

What is claimed is:
 1. A system comprising a glass substrate and a coating applied to the glass substrate, the coating comprising a plurality of layers, wherein at least one of the layers includes a Nickel-Chromium-Molybdenum superalloy and at least two additional layers include silver, wherein the superalloy comprises about 58% or more Ni, about 20 to about 23% Cr, about 8 to about 10% Mo, about 3.15 to about 4.15% Nb+Ta and a maximum of about 5% Fe by weight, wherein the system has an emissivity of about 0.030 to about 0.039, and wherein the system has a b_(h) color coordinate value of about −7 to about −11 as measured in Hunter Lab color space.
 2. The system of claim 1, wherein the layer including the superalloy has a thickness ranging from about 30 to about 150 angstroms, and wherein the at least two additional layers including silver comprise a first silver layer having a thickness ranging from about 80 to about 150 angstroms and a second silver layer having a thickness ranging from about 80 to about 150 angstroms.
 3. The system of claim 1, wherein the plurality of layers is arranged such that the layer including the superalloy is positioned between the glass substrate and at least one of the at least two additional layers including silver.
 4. The system of claim 3, wherein the at least two additional layers including silver are formed of a first layer including silver and a second layer including silver, and wherein the plurality of layers includes a bottom oxide layer positioned between the glass substrate and the layer including the superalloy, a middle oxide layer positioned between the first layer including silver and the second layer including silver, and a top oxide layer adjacent the second layer including silver on a side of the second layer including silver opposite the middle oxide layer.
 5. The system of claim 4, wherein the bottom oxide layer has a thickness ranging from about 360 to about 400 angstroms, the middle oxide layer has a thickness ranging from about 550 to about 700 angstroms, and the top oxide layer has a thickness ranging from about 110 to about 140 angstroms.
 6. The system of claim 4, wherein the plurality of layers further comprises an overcoat layer.
 7. The system of claim 4, wherein the bottom oxide layer, the middle oxide layer and top oxide layer include an oxide selected from the group consisting of a zinc oxide, a tin oxide, and a zinc tin oxide.
 8. The system of claim 4, further comprising a first barrier layer positioned between the first layer including silver and the middle oxide layer and a second barrier layer positioned between the second layer including silver and the top oxide layer.
 9. A substrate coating on a glass substrate, the substrate coating comprising a plurality of layers on the glass substrate, the plurality of layers comprising: a first layer comprising a metal oxide having a thickness ranging from about 360 to about 400 angstroms, a second layer comprising a Nickel-Chromium-Molybdenum superalloy wherein the superalloy comprises about 58% or more Ni, about 20 to about 23% Cr, about 8 to about 10% Mo, about 3.15 to about 4.15% Nb+Ta and a maximum of about 5% Fe by weight, and a third layer comprising silver, wherein the second layer comprising the superalloy is between the first layer comprising the metal oxide and third layers comprising silver in the plurality of layers on the glass substrate, and wherein the substrate coating on a glass substrate has a b_(h) color coordinate value of about −7 to about −11 as measured in Hunter Lab color space.
 10. The substrate coating of claim 9, wherein the second layer comprising the superalloy has a thickness ranging from about 30 to about 150 angstroms and the third layer comprising silver has a thickness ranging from about 80 to about 150 angstroms.
 11. A glass unit comprising a glass substrate and a coating comprising a plurality of layers on the glass substrate, the plurality of layers comprising: a metal oxide layer comprising a metal oxide, a superalloy layer comprising a Nickel-Chromium-Molybdenum superalloy, wherein the superalloy comprises about 58% or more Ni, about 20 to about 23% Cr, about 8 to about 10% Mo, about 3.15 to about 4.15% Nb+Ta and a maximum of about 5% Fe by weight, and a silver layer, wherein the superalloy layer is between the metal oxide layer and the silver layer in the plurality of layers on the glass substrate, and wherein the glass unit has a b_(h) color coordinate value of about −7 to about −11 as measured in Hunter Lab color space.
 12. The glass unit of claim 11, wherein the superalloy layer has a thickness ranging from about 30 to about 150 angstroms and the silver layer has a thickness ranging from about 80 to about 150 angstroms.
 13. The substrate coating or the glass unit of any of claims 9, 10 through 11 and 12, wherein the metal oxide comprises tin oxide, zinc oxide or a mixture thereof.
 14. An article comprising a glass substrate and a coating applied to the glass substrate, the coating comprising a plurality of layers, from the glass substrate outwardly: a) a bottom layer comprising a metal oxide layer and having a thickness ranging from about 360 to about 400 angstroms; b) a superalloy layer comprising a Nickel-Chromium-Molybdenum superalloy, having a thickness ran in from about 30 to about 150 angstroms wherein the superalloy comprises about 58% or more Ni, about 20 to about 23% Cr, about 8 to about 10% Mo, about 3.15 to about 4.15% Nb+Ta and a maximum of about 5% Fe by weight; c) a first silver layer having a thickness ranging from about 80 to about 150 angstroms; d) a middle metal oxide layer having a thickness ranging from about 550 to about 700 angstroms; e) a second silver layer having a thickness ranging from about 80 to about 150 angstroms; f) a top metal oxide layer having a thickness ranging from about 110 to about 140 angstroms; and wherein the article has an emissivity of about 0.030 to about 0.039 and a b_(h) color coordinate value of about −7 to about −11 as measured in Hunter Lab color space.
 15. The article of claim 14, wherein the article has an emissivity of about 0.030 to about 0.035.
 16. An article comprising a glass substrate and a coating applied to the glass substrate, the coating comprising a plurality of layers including: one or more metal oxide layers; one or more silver layers; and at least one Nickel-Chromium-Molybdenum superalloy layer, wherein the superalloy comprises about 58% or more Ni, about 20 to about 23% Cr, about 8 to about 10% Mo, about 3.15 to about 4.15% Nb+Ta and a maximum of about 5% Fe by weight, therebetween; wherein the article has a b_(h) color coordinate value of about −7 to about −11 as measured in Hunter Lab color space, and an emissivity of about 0.030 to about 0.039.
 17. The article of claim 16, wherein the article has a b_(h) color coordinate value of about −8 to about −10 as measured in Hunter Lab color space.
 18. The article of claim 17, wherein the article has an emissivity of about 0.030 to about 0.035.
 19. The article of claim 16, wherein the superalloy layer has a thickness ranging from about 30 to about 150 angstroms.
 20. The article of claim 19, wherein the plurality of layers comprises, from the glass substrate outwardly: a) a bottom metal oxide layer of the one or more metal oxide layers, the bottom metal oxide layer having a thickness ranging from about 360 to about 400 angstroms; b) the at least one superalloy layer; c) a first silver layer of the one or more silver layers, the first silver layer having a thickness ranging from about 80 to about 150 angstroms; d) a middle metal oxide layer of the one or more metal oxide layers, the middle metal oxide layer having a thickness ranging from about 550 to about 700 angstroms; e) a second silver layer of the one or more silver layers, the second silver layer having a thickness ranging from about 80 to about 150 angstroms; and f) a top metal oxide layer of the one or more metal oxide layers, the top metal oxide layer having a thickness ranging from about 110 to about 140 angstroms.
 21. An insulating glass unit comprised of: at least two substantially parallel, spaced sheets of glass, said two sheets of glass being sealed together at their peripheral edges thereby to define an insulating chamber therebetween, a coating applied to a surface of one of said glass sheets within said insulating chamber, wherein said coating comprises a plurality of layers, and wherein the plurality of layers includes: a bottom metal oxide layer having a thickness ranging from about 360 to about 400 angstroms; a superalloy layer comprising a Nickel-Chromium-Molybdenum superalloy, wherein the superalloy comprises about 58% or more Ni, about 20 to about 23% Cr, about 8 to about 10% Mo, about 3.15 to about 4.15% Nb+Ta and a maximum of about 5% Fe by weight; and at least one and no more than two silver layers; wherein the superalloy layer is between the bottom metal oxide layer and at least one of the silver layers in the plurality of layers on the surface of the sheet of glass to which the coating is applied, wherein the insulating glass unit has an SHGC (or solar heat gain coefficient) of about 0.140 to about 0.300, a b_(h) color coordinate value of about −7 to about −11 as measured in Hunter Lab color space, and an emissivity of about 0.030 to about 0.039.
 22. The insulating glass unit of claim 21, wherein the insulating glass unit has an SHGC (or solar heat gain coefficient) of about 0.140 to about 0.260.
 23. The insulating glass unit of claim 21, wherein the superalloy layer has a thickness ranging from about 30 to about 150 angstroms.
 24. The insulating glass unit of claim 23, wherein the plurality of layers comprises, from the surface of the sheet of glass to which the coating is applied outwardly: a) the bottom metal oxide layer; b) the superalloy layer; c) a first silver layer of the at least one and no more than two silver layers, the first silver layer having a thickness ranging from about 80 to about 150 angstroms; d) an additional middle metal oxide layer having a thickness ranging from about 550 to about 700 angstroms; e) a second silver layer of the at least one and no more than two silver layers, the second silver layer having a thickness ranging from about 80 to about 150 angstroms; f) an additional top metal oxide layer having a thickness ranging from about 110 to about 140 angstroms.
 25. An article comprising: a glass substrate having a pair of major surfaces; and a coating applied to at least one of the major surfaces of the glass substrate, the coating comprising a plurality of layers including: at least one metal oxide layer having a thickness ranging from about 360 to about 400 angstroms; at least one and no more than two silver layers; and a superalloy layer comprising a Nickel-Chromium-Molybdenum superalloy, wherein the superalloy comprises about 58% or more Ni, about 20 to about 23% Cr, about 8 to about 10% Mo, about 3.15 to about 4.15% Nb+Ta and a maximum of about 5% Fe by weight; wherein the superalloy layer is between the metal oxide layer and at least one of the silver layers in the plurality of layers on the glass substrate; and wherein the color coordinate values of the article from a direction that is substantially normal to the coated major surface are substantially equal to the color coordinate values from directions that are acute to the coated major surface, and an emissivity of about 0.030 to about 0.039; and wherein the article has a b_(h) color coordinate value of about −7 to about −11 as measured in Hunter Lab color space.
 26. A method of coating a glass substrate, the coating comprising a plurality of layers, wherein at least one of the layers includes a Nickel-Chromium-Molybdenum superalloy material and at least two additional layers include silver materials, wherein the superalloy material comprises about 58% or more Ni, about 20 to about 23% Cr, about 8 to about 10% Mo, about 3.15 to about 4.15% Nb+Ta and a maximum of about 5% Fe by weight, wherein the coated glass substrate has a b_(h) color coordinate value of about −7 to about −11 as measured in Hunter Lab color space, the method comprising: applying a bottom oxide layer to the glass substrate by sputtering; applying a layer comprising the Nickel-Chromium-Molybdenum superalloy material by sputtering; applying a layer comprising a first layer of silver material by sputtering; applying a first barrier layer comprising titanium by sputtering; Applying a middle oxide layer by sputtering; applying a layer comprising a second layer of silver material by sputtering, applying a second barrier layer comprising titanium by sputtering; applying a top oxide layer by sputtering.
 27. The method of claim 26, wherein the applying steps occur in a coater having a plurality of coating zones and the glass substrate is conveyed within the coater through the plurality of coating zones.
 28. The method of claim 27, wherein: the bottom oxide layer is applied in a first coat zone by sputtering a plurality of targets including at least one zinc target and at least one tin target, the superalloy material is applied in a second coat zone by sputtering a target of superalloy to deposit the superalloy material, the silver material is applied in the second coat zone by sputtering a target of silver to deposit the first silver layer, the first barrier layer is applied in the second coat zone by sputtering a target including titanium, the middle oxide layer is applied in at least a third coat zone by sputtering a plurality of targets including at least one zinc target and at least one tin target, the additional silver material is applied in a fifth coat zone by sputtering an additional target of silver to deposit the second silver layer, the second barrier layer is applied in the fifth coat zone by sputtering an additional target including titanium, and the top oxide layer is applied in a sixth coat zone by sputtering a plurality of targets including at least one zinc target and at least one tin target.
 29. The method of claim 28, further comprising applying an overcoat to the top oxide layer by sputtering a target including titanium to deposit the overcoat comprising a titanium oxide following the application of the top oxide layer in the sixth coat zone.
 30. The method of claim 26, wherein: the layer of the Nickel-Chromium-Molybdenum superalloy material is applied at a thickness ranging from about 30 to about 150 angstroms, the first layer of silver material is applied at a thickness ranging from about 80 to about 150 angstroms, the second layer of silver material is applied at a thickness ranging from about 80 to about 150 angstroms, the bottom oxide layer is applied at a thickness ranging from about 360 to about 400 angstroms, the middle oxide layer is applied at a thickness ranging from about 550 to about 700 angstroms, and the top oxide layer is applied at a thickness ranging from about 110 to about 140 angstroms.
 31. The method of claim 26, further comprising: applying an overcoat layer to the top oxide layer by sputtering following the step of applying a top oxide layer. 